The Human Plasma Proteome Draft of 2017: Building on the Human

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The Human Plasma Proteome Draft of 2017: Building on the Human Plasma PeptideAtlas from Mass Spectrometry and Complementary Assays Jochen M Schwenk, Gilbert S Omenn, Zhi Sun, David S Campbell, Mark S. Baker, Christopher M Overall, Ruedi Aebersold, Robert L. Moritz, and Eric W. Deutsch J. Proteome Res., Just Accepted Manuscript • DOI: 10.1021/acs.jproteome.7b00467 • Publication Date (Web): 22 Sep 2017 Downloaded from http://pubs.acs.org on September 24, 2017

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The Human Plasma Proteome Draft of 2017: Building on the Human Plasma PeptideAtlas from Mass Spectrometry and Complementary Assays

Jochen M. Schwenk1,*, Gilbert S. Omenn2,3, Zhi Sun3, David S. Campbell3, Mark S. Baker4, Christopher M. Overall5, Ruedi Aebersold6,7, Robert L. Moritz3, and Eric W. Deutsch3,*

1

Affinity Proteomics, SciLifeLab, School of Biotechnology, KTH Royal Institute of Technology, Tomtebodavägen 23, SE-171 65 Solna, Sweden 2 Departments of Computational Medicine & Bioinformatics, Internal Medicine, and Human Genetics and School of Public Health, University of Michigan, Ann Arbor, MI, 48109-2218, USA 3 Institute for Systems Biology, Seattle, WA, USA 4 Department of Biomedical Sciences, Faculty of Medicine and Health Science, Macquarie University, NSW, 2109. Australia 5 Centre for Blood Research, Departments of Oral Biological & Medical Sciences, and Biochemistry & Molecular Biology, Faculty of Dentistry, University of British Columbia, Vancouver, Canada 6 Department of Biology, Institute of Molecular Systems Biology, ETH Zurich, Zurich, Switzerland 7 Faculty of Science, University of Zurich, 8006 Zurich, Switzerland *Address correspondence to: Eric W. Deutsch, Institute for Systems Biology, 401 Terry Ave N, Seattle, WA 98109, USA, Email: [email protected], Phone: 206-732-1200, Fax: 206-732-1299; and Jochen M. Schwenk, SciLifeLab, School of Biotechnology, KTH Royal Institute of Technology, Tomtebodavägen 23, SE-171 65 Solna, Sweden, Email: [email protected]

Keywords: Human Proteome Project, mass spectrometry, plasma, proteomics.

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Abstract Human blood plasma provides a highly accessible window to the proteome of any individual in health and disease. Since its inception in 2002, the Human Proteome Organization’s Human Plasma Proteome Project (HPPP) has been promoting advances in the study and understanding of the full protein complement of human plasma and on determining the abundance and modifications of its components. In 2017, we review the history of the HPPP and the advances of human plasma proteomics in general, including several recent achievements. We then present the latest 2017-04 build of Human Plasma PeptideAtlas, which yields ~43 million peptide-spectrum matches and 122,730 distinct peptide sequences from 178 individual experiments at a 1% protein-level FDR globally across all experiments. Applying the latest Human Proteome Project Data Interpretation Guidelines, we catalog 3509 proteins that have at least two non-nested uniquely-mapping peptides of 9 amino acids or more and >1300 additional proteins with ambiguous evidence. We apply the same two-peptide guideline to historical PeptideAtlas builds going back to 2006 and examine the progress made in the past ten years in plasma proteome coverage. We also compare the distribution of proteins in historical PeptideAtlas builds in various RNA-abundance and cellular localization categories. We then discuss advances in plasma proteomics based on targeted mass spectrometry as well as affinity assays, which during early 2017 target ~2000 proteins. Finally we describe considerations about sample handling and study design, concluding with an outlook for future advances in deciphering the human plasma proteome.

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Introduction Human blood is the most informative easily obtainable sample for assessing the wellness of an individual. Cells can be isolated to provide genomic, transcriptomic, proteomic, metabolomic, and epigenomic information, and the plasma can yield a wealth of systemic information based on the abundance of proteins, cell-free DNA and RNA, metabolites, lipids, and other small molecules. Blood is in contact with all internal organs and, therefore, contains signatures of normal function as well as the consequences of cellular damage and disease manifestation throughout the body. However, the abundances of proteins and other molecules vary across an enormous dynamic range (~1013 range), making the task of detecting and quantifying low abundance signatures a difficult challenge (1). The plasma proteome, therefore, is immensely important clinically and presents enormous analytical challenges.

As one of the very first initiatives of the Human Proteome Organization (2) (HUPO), the Human Plasma Proteome Project (HPPP) began in 2002 with the aim of establishing a comprehensive profile of the proteins present in human plasma in health and disease. The initial phase of the HPPP was a collaborative effort among 35 laboratories to catalog the human plasma proteome via mass spectrometry (MS) based on a set of defined reference samples of plasma and serum (3). The HPPP continues its efforts to the present day with MS as well as exploring orthogonal technologies.

The global Human Proteome Project (HPP) was announced in 2010 at the 10th HUPO World Congress in Sydney, Australia, with the aim of advancing our understanding of all proteins in the human proteome and making advanced protein measurement assays more accessible to the broader research community (4). The HPP comprises a chromosome-centric project (C-HPP; launched at HUPO 2011 in Geneva, Switzerland) (5) that aims to identify and characterize all proteins, annotated in an internationally distributed fashion; a biology/disease-focused project (B/D-HPP; launched at HUPO 2012 in Boston, USA) (6) that aims to understand better the complement of human proteins that are pertinent to a wide

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variety of human organ systems and biofluids in health and disease; and three resource pillars, including antibody profiling, mass spectrometry, and knowledge base/bioinformatics. The HPPP is one of the major initiatives of the B/D-HPP, focused on understanding the full complement of proteins that can be detected and measured in human plasma samples both in normal and diseased states.

In this article, we first provide a brief review of the advances of the HPPP and MS-based human plasma proteomics in general over the past 15 years. We present the latest and most comprehensive compendium of proteins that have been confidently detected in human plasma samples from the aggregated spectra generated in a large number of publicly available studies. We then discuss advances in MS, present other technologies beyond MS, and conclude with recommendations and an outlook for progress for the next five years.

Historical Perspective of Plasma Analysis with MS The earliest large compendium of plasma proteins was presented in 2002 in the seminal article by Anderson & Anderson (1). The list of 289 proteins was collected from literature of the day. In a classic figure, a subset of proteins with abundances was depicted over 10 orders of magnitude in abundance in normal plasma and grouped broadly into the categories of classical plasma proteins, tissue leakage products, and cytokines and other very low abundance proteins. Most of the proteins were listed in a table with typical reported concentrations from ELISA (or similar technology) measurements.

In 2003 the HPPP obtained and distributed a series of serum and EDTA-, citrate-, and heparinanticoagulated plasma samples from Caucasian, African-American, and Asian-American individuals to 35 different laboratories to run across a range of MS instruments and analysis of choice and report the resulting lists of peptides and proteins. There was tremendous variability in the reported results, with some groups providing a rather shallow analysis of one or two of the distributed samples, while other

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groups provided a far deeper analysis with substantial fractionation of many more samples. This heterogeneity made it particularly difficult to compare results among different groups. In the final HPPP report (3), the number of non-redundant proteins with one or more peptides reported by any group was over 9000. A more conservative list of proteins with at least two reported peptides amounted to 3020 proteins and those with three peptides to 1500 proteins. The danger of very high numbers of false positives from combining many such data lists was explicitly suspected. A subsequent, far more conservative analysis of the results by the same HPPP investigators concluded that there existed high confidence evidence for 889 proteins (7). This analysis uniquely used a Bonferroni-type adjustment for multiple comparisons. An independent analysis of the raw data from most (but not all) of the labs as well as some additional data sets yielded a similar estimate of 960 proteins (8).

Around the same time, several other labs made attempts at defining the MS-observable human plasma proteome. In retrospect, some of these attempts also suffered from substantially inflated numbers due to improperly controlled false positives. In 2008, a meticulous manually-validated effort using the latest instrumentation yielded only 697 proteins, albeit with 144 immunoglobulin entries removed (9). Although combining data sets from different investigators and platforms provides access to a higher number of legitimate detections, it also makes controlling the false discovery rate (FDR) far more challenging.

It was widely recognized that the most abundant proteins greatly complicated detection of much lower abundance proteins and their peptides. Antibody-based depletion of 1 (albumin), 6, 14, or 22 most abundant proteins (accounting for 50 to 99% of the protein mass) became common (10-12), with deeper in-house depletion methods also recently developed (13, 14).

Subsequently the PeptideAtlas resource collected many additional data sets from many different labs and provided substantial effort into controlling the FDR of the search results to provide a database of human plasma proteins with an approximate 1% FDR at the protein level across all experiments as an ensemble.

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In 2011 Farrah et al. reported 1929 proteins with a 1% protein-level FDR, along with estimated concentrations of the identified proteins based on PSM counting statistics across all datasets in the PeptideAtlas build (15). In 2013, 3553 non-redundant proteins were reported (16). In 2014, Farrah et al. extensively compared the proteomes of plasma, kidney, and urine, detecting proteins filtered from the plasma through the kidney to the urine, proteins appearing de novo in the urine, and proteins arising in the kidney (17).

More recent work has pushed the number of confidently-identified plasma proteome even higher. Keshishian et al. (18) reported on human plasma derived from four patients undergoing a planned myocardial infarction procedure for hypertrophic cardiomyopathy. Plasma was sampled at multiple time points, depleted of the ~64 most abundant proteins, cleaved with two proteases, labeled with iTRAQ reagents, fractionated by pH 10 RP-HPLC into 30 concatenated pools, and analyzed with modern high resolution Q Exactive Plus Orbitrap instrumentation. Whereas 3400 proteins were quantified in every sample, a total of 5300 distinct protein entries were claimed in at least one of the samples, with an estimated protein-level FDR 50, medium: FPKM 10-50, low: FPKM 10-0.5; not detected: FPKM 0.5-0) (38, 39)). We note that correlation between RNA abundances and protein abundances is a subject of extensive discussions and generally low (e.g. (40)), but the completeness of RNA abundances is far higher and enables nearly complete comparisons with several protein sets. In Table 1 we show the relative distributions of proteins within these high, medium, low and not detected categories. While 42% of the population of all protein-coding genes from Ensembl (release 88.38) falls into the high RNA-abundance category in highest-expressed tissues, a somewhat higher percentage (50%) of proteins detected in all human samples are in this high abundance category, and in the Plasma PeptideAtlas an even higher percentage (77%) are in this high RNA abundance category. The total number of plasma proteins differs slightly from the figure of 3509 in the abstract and other totals in this article because there is a small number of proteins that could not be mapped to the RNA expression tables. The union of a broad range of immunoassays publicly available for plasma analysis during spring of 2017 was collected from five providers. The corresponding protein-coding genes for these targets were annotated with regards to their predicted location and RNA abundance using HPA: Somalogic (N = 1278), Olink (N = 978), R&D Systems (N = 540), Myriad RBM (N = 302) and Abcam (N = 238). For immunoassays, a greater number of targets are represented in the low RNA-abundance category than for the Plasma PeptideAtlas. The union of the 1918 proteins targeted by immunoassays and the 3429 Plasma PeptideAtlas proteins overlap by 1087 proteins.

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Annotated RNA expression Source

Data type

Sample

Total

High > 50 FPKM

Medium 50-10 FPKM

Low 10-0.5 FPKM

Not detected 0.5-0 FPKM

Ensembl

Protein encoding genes

Tissues

19,613

8,283 (42%)

7,687 (39%)

2,539 (13%)

1,104 (6%)

PeptideAtlas

Peptides

Tissues

15,013

7,555 (50%)

6,212 (41%)

1,114 (7%)

132 (1%)

PeptideAtlas

Peptides

Plasma

3,429

2,624 (77%)

676 (20%)

103 (3%)

26 (1%)

Various

Immunoassays

Plasma

1,918

1,281 (67%)

476 (25%)

126 (7%)

35 (2%)

Table 1. Distribution of several sets of proteins as a function of RNA abundance categories from the Human Protein Atlas. Various sources were used to collect immunoassays for plasma analysis.

In Table 2, we show the distribution of proteins detected in the Human Plasma PeptideAtlas over time as a function of RNA abundance categories from the Human Protein Atlas. In 2009, only ~10% of the proteins in the Plasma PeptideAtlas were found in the medium and low RNA-abundance categories, while as of 2017, nearly a quarter of all high-confidence detections are proteins with corresponding medium and low RNA-abundance. The distributions of plasma protein concentrations in relation to these RNA expression categories can be found in Supplementary Figure 1.

Annotated RNA expression Build

Total

High > 50 FPKM

Medium 50-10 FPKM

Low 10-0.5 FPKM

Not detected 0.5-0 FPKM

2009

1,011

891 (88%)

89 (9%)

22 (2%)

9 (1%)

2010

1,013

893 (88%)

89 (9%)

22 (2%)

9 (1%)

2013

2,109

1698 (81%)

330 (16%)

60 (3%)

21 (1%)

2015

2,880

2211 (77%)

550 (19%)

95 (3%)

24 (1%)

2017

3,429

2624 (77%)

676 (20%)

103 (3%)

26 (1%)

Table 2. Distribution of proteins detected in the Human Plasma PeptideAtlas over time as a function of RNA abundance categories from the Human Protein Atlas.

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In Table 3, we used the protein abundance from the 2017 Human Plasma PeptideAtlas to show the concentration distribution and increase in coverage from previous builds. A 33-fold increase in coverage was seen for low abundant proteins (< 0.1 ng/ml). Protein Concentration [ng/ml]

Total N (%)

> 1000

1000-10

10-0.1

< 0.1

2009

1008 (100%)

237 (24%)

495 (49%)

259 (26%)

17 (2%)

2010

1010 (100%)

237 (23%)

495 (49%)

261 (26%)

17 (2%)

2013

2139 (100%)

257 (12%)

791 (37%)

991 (46%)

100 (5%)

2015

2944 (100%)

288 (10%)

844 (29%)

1458 (50%)

354 (12%)

2017

3521 (100%)

309 (9%)

913 (26%)

1726 (49%)

573 (16%)

Build

Table 3. Distribution of the estimated protein concentration by abundance categories from the 2017 Human Plasma PeptideAtlas and previous builds adjusted to same criteria.

In Table 4, we show the numbers and percentages of proteins in the Plasma PeptideAtlas builds since 2009 in relation to their localizations predicted from protein sequences (39, 41). Between 2015 and 2017, the coverage for secreted proteins hardly changed, accompanied by a marked increase in the percentage of membrane and intracellular proteins.

SecretedMembraneIntracellular

Secreted

SecretedMembrane

IntracellularSecreted

Membrane

IntracellularMembrane

Intracellular

ALL

298 (100%)

1229 (100%)

386 (100%)

1020 (100%)

3103 (100%)

1693 (100%)

11884 (100%)

2017

127 (43%)

421 (34%)

133 (34%)

422 (41%)

320 (10%)

300 (18%)

1706 (14%)

2015

124 (42%)

412 (34%)

128 (33%)

407 (40%)

243 (8%)

233 (14%)

1333 (11%)

2013

99 (33%)

331 (27%)

92 (24%)

299 (29%)

176 (6%)

148 (9%)

964 (8%)

2009

28 (9%)

200 (16%)

28 (7%)

175 (17%)

51 (2%)

47 (3%)

482 (4%)

Imm

100 (34%)

403 (33%)

126 (33%)

268 (26%)

205 (7%)

179 (11%)

637 (5%)

Table 4. Distribution of proteins detected in the Human Plasma PeptideAtlas over time as a function of localization categories from the Human Protein Atlas. The first row shows the distribution of annotations for all protein-encoding genes; the last row lists corresponding values for the immunoassays described in Table 1.

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For the 2017 build, the distributions of concentrations in relation to the predicated protein localization (categorized in intracellular, secreted and membrane only) are illustrated in Supplementary Figure 2.

Targeted MS assays for the plasma proteome While most of the efforts to expand the known plasma proteome have used shotgun proteomics techniques, the selected reaction monitoring (SRM) technique has been widely used to achieve more consistent, quantitative, and sensitive measurements of specific proteins of interest in plasma. SRM workflows are more difficult to deploy due to the requirement for predetermining effective signatures for each targeted protein, the need for spiking in heavy-labeled reference peptides for accurate quantitation, and the limited number (~200 – 1000) of those signatures that can be monitored per MS run. However, this extra effort required to carry out measurements is offset by improved sensitivity and specificity, high degree of quantitative accuracy and reproducibility, and the determination of upper limits of abundance for each targeted peptide. The earliest work by Anderson & Hunter (42) developed targeted assays (also known as multiple reaction monitoring (MRM) targeting 53 high and medium abundance proteins over 4.5 logs in abundance with a coefficient of variation (CV) of < 10% for most of them. This was followed by many other studies that have defined and demonstrated the effectiveness of signatures for certain proteins of interest (43-46). Of particular interest was the deployment of SRM assays over several MS runs for over 1000 cancer associated proteins and the detection of 182 of these cancer associated proteins in plasma covering 5 orders of magnitude (47).

To provide assistance in deploying targeted SRM assays, the SRMAtlas resource (48) was developed using highly characterized synthetic peptides representing the most proteotypic candidates of each protein, their variants, including spliced and non-synonymous variants, and some post-translational modifications. The human SRMAtlas has now determined recommended signatures for multiple peptides per protein for over 99% of all human proteins, enabling researchers to target any protein of interest

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without needing to undergo a lengthy signature selection process, fragment ion selection and SRM assay construction.

To further advance targeted quantitative proteomics, multiplexed fragment ion monitoring based assays have been developed into a technique, broadly termed data-independent acquisition (DIA), including SWATH-MS (49). SWATH-MS promises to provide similar sensitivity and specificity as SRM, without the problems associated with selecting targets in advance, by utilizing a well characterized spectral library developed a priori or on the fly (50, 51). In essence, high-resolution fragment ion data are collected for all peptides across chromatographic peaks above the detection threshold in a sample, but at the cost of substantially more complex informatics analysis after acquisition, which is needed to disentangle the high level of multiplexing in the data. DIA techniques perform well in comparison with SRM (52). Large scale-studies of over 1000 plasma proteins in many plasma samples are now feasible (53, 54), and also enable the study of unexpected post-translational modifications within the comprehensive multiplexed datasets (55, 56).

Affinity assays for the plasma proteome As described above, the main driving force for defining new components of the plasma proteome has been mass spectrometric. An alternative for determining the constituent proteins in plasma is the use of affinity reagents to capture, enrich, and detect their target proteins. The use of such assays has provided general as well as clinically applied insights into the protein composition of body fluids, starting from albumin down to low abundance molecules, such as cytokines.

Affinity-based approaches require knowledge about which proteins are to be measured, and hence are by definition targeted assays. A primary bottleneck for expansion to a wider range of proteins has been linked to the availability of affinity reagents (57). According to Antibodypedia (www.antibodypedia.org;

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access date 2017-05-11; (58)) there are more than 2.8 million antibody reagents commercially available. Even though these cover 94% of the protein encoding genes, enormous effort is still required to validate and annotate their utility for the intended assay type and technology platform, as well as the sample type, preparation and formulation. For highly multiplexed assays, compatibility between different assay components also needs further attention. Recent discussions have indeed raised concerns about the reliability of affinity-based assays due to lack of reproducibility and specificity (59, 60). The community has therefore brought forward suggestions for how to apply communal standards on how to validate these reagents (61). The performance of reagents is indeed dependent on the application and sample type and needs to be assessed for every binder and every assay. A systematic approach using MS to qualify antibodies for their use in plasma proteomics assays has just recently been described (62). While the generation of natural or synthetic affinity reagents is discussed in detail elsewhere (63), and an increasing diversity of reagent types is making them attractive across the different fields of life science, they must be assessed separately for their use in plasma assays and the applied technologies.

Assay platforms Today there are a variety of multiplexed assay technologies available to detect proteins in plasma (64). Whereas affinity reagents are also used in combination with MS (65, 66), the primary applications for plasma are driven towards high throughput assays in terms of sample and proteins. Here, multiplexing is achieved by different concepts such as coding the features either via their location (e.g. on a planar support or in channels) or with color or DNA barcode. Detection is then most often achieved via fluorescently labelled reporters or barcodes of oligonucleotides for amplification, hybridization or sequencing. A general feature of multiplexed affinity assays is that small quantities of samples (< 50 µl) suffice for a single highly multiplexed analysis or sets of medium-sized multiplexed analyses. Prefractionation is generally not required. In addition, larger sets of samples (N > 100) can be analyzed within a single lab day, since most assays are performed in microtiter plates for which automation solutions exist. Technological advances have further led to the availability of assays with very high

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sensitivity (fg/ml) (67). Nevertheless, the number of protein assays and degree of multiplexing remains limited in most applications, in particular when compared to MS. Challenges for immunoassays relate to interference, incompatibility of assay components causing cross-reactivity, different sample dilutions needed for reaching the optimal analytical window, assay specificity, and analytical selectivity (68).

In the long run, technologies that are capable of measuring proteins in multiplex and in a large number of samples will be beneficial for rapid analysis of plasma (69). One attractive solution is described for coupling multiplexed protein detection with read-out by DNA and to profile more than 90 proteins in a single assay (70, 71); they have been used and applied in extensive sample sets (72, 73). While these proximity extension assays use two binders per target protein, other large scale techniques employ single affinity reagents for high multiplexing capabilities. Those exist on planar arrays (74) as well as on colorcoded beads (75), but both come at the expense of sensitivity and specificity, hence require complex validation schemes to assure the identity of the captured protein (76). Another single binder concept that has seen broad usage is based on modified aptamers that have been engineered to both enrich proteins from plasma and serve as the detection agent (77). The signatures of the obtained plasma profiles were associated with the protein quantitative trait loci (pQTLs) for validation (78). Recently, the system has been expanded in the number of targets per assay to 3000 proteins (79), and assays with 5000 proteins are under development although have not been released as of September 2017 (personal communication). The utilized selection technology and introduction of additional modifications may be one approach to enable the generation of even larger libraries of affinity binders, possibly reaching a possible proteome-wide coverage (80).

To provide insights into the current portfolio of immunoassays with data from MS, we collected protein assays offered by five commercial immunoassays providers, as introduced above (see Comparisons with RNA abundances). Cumulatively, these five resources constituted 1918 unique targets as of spring 2017, and provide an alternative starting point for a description of the protein assays with plasma. Out of these

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1918 proteins, a set of 831 proteins were only detectable by immunoassays when compared to the 2017 build of the Human Plasma PeptideAtlas, leaving 1087 proteins detected in both. The 2017 Human Plasma PeptideAtlas contained a further 2422 proteins that remained addressed only by MS-based methods. We investigated the functional differences between the proteins covered by the two technologies by assessing their Gene Ontology (GO) term distribution using ToppCluster (81). This revealed that terms for cytokine related proteins were enriched for immunoassays (GO:0005126, GO:0005125, GO:0008009, GO:0042379). For MS, terms related to structural elements (GO:0005198, GO:0008092, GO:0003779, GO:0051015) were enriched (see also Supplementary Table 2). This indicates that (i) many low abundant proteins are still difficult to detect in plasma when using MS and that (ii) cellular proteins are found in plasma but are underrepresented in the portfolio of immunoassays. Lastly, our investigation revealed 1087 proteins found to be detectable with both technologies. GO analysis for these proteins revealed terms such as protein complex binding (GO:0032403; N =172), extracellular space (GO:0005615; N =466), cell mobility (GO:0048870; N =304), localization (GO:0051674; N =304) and cell migration (GO:0016477; N =295). These ~1000 proteins can provide a starting point for comparing the two technologies with the purpose of validating each other in increasing numbers of samples, studies and diseases. Eventually, databases such as PeptideAtlas should also be created for the widely used immunoassays to collect data and the concentrations of proteins found in plasma. These initiatives could also follow examples of the NCI assay portal (82) that currently hosts 1,517 quantitative mass spectrometry-based proteomic assays targeted for 820 proteins. In this portal, 374 assays listed for plasma or serum derived samples target 192 unique proteins.

Affinity assays will assist in our understanding of the plasma proteome once validated and sensitive assays exist for even more protein targets and for those currently not detectable by MS. The immunoassays are attractive for studies with larger sample numbers, especially if the amount of material is limited, but still less for de novo discovery purposes. Quantification remains a challenge for today’s immunoassay, since different standards are often used by different assay providers, and their detectability

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may differ from that of the protein found in-vivo. The emerging systems that offer either highly multiplexed or highly sensitive assays will accelerate our knowledge about the plasma proteome and move beyond the well-studied markers of inflammation. Specificity also remains a major challenge for affinity assays, as reflected in the goals of the International Working Group on Antibody Validation (61).

Considerations about samples in plasma proteomics Studies aiming to determine the plasma proteome have largely been limited either by the number of targets or in terms of sample numbers. It is therefore likely that, if only a few phenotypes are used, the initial indications cannot be confirmed in an independent set of samples. Hence, the sample number of plasma proteomic studies must increase. Furthermore, plasma is a specimen that is attractive because it is accessible from a large number of subjects and frequently hosted by biobanks, although many are populated mainly with blood sera (83). Since the recommendations of the Human Proteome Project in 2006 (3), most plasma samples have used EDTA as anticoagulant; however, some specimens are still anticoagulated with heparin or citrate. Further, multitudes of dried blood spot cards known as Guthrie cards are available since the early 1960’s for all newborns almost worldwide providing a large resource for blood-based proteomics (84-86). This provides opportunities for new discoveries and is assisted by expanded metadata about each donor (health status and history) as well as the pre-analytical conditions related to the sample. However, both must be acknowledged and considered more carefully. The community is indeed becoming more aware that these sample related parameters may contribute to the detectability of a protein and thereby influence the outcome and reproducibility of a study (87-89). Hence, guidelines for the parameters related to the sample, such as blood draw (time point of collection, location), collection procedure (tube type, handling conditions), storage (aliquoting, container, temperature), use (thawing procedure, freeze-thawing cycles) as well as alternative formulation (dried plasma or blood spots), should therefore be considered and included in the experimental planning and

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downstream data analysis. A categorization of sample-related parameters can already be obtained (90) and a wider use of such codes will further enhance the validity of studies in plasma.

Conclusion The advances in MS technologies continue to push our ability to detect and quantify a large number of proteins with high specificity and quantitative accuracy. Yet, affinity capture reagent technologies outperform MS in terms of sensitivity and speed. Ongoing efforts to better characterize affinity capture reagents in a given sample holds the potential to improve the specificity and reliability of the assays in which these are used. The combination of these two technologies is probably underutilized today, having the potential to combine the sensitivity of affinity capture and specificity of MS, albeit still with the lower speed of MS. We have presented the 2017-04 latest build of the Human Plasma PeptideAtlas, with 3509 core neXtProt proteins meeting guideline # 15 of the HPP MS Data Interpretation Guidelines. In comparison with older plasma builds, the addition of datasets with high resolution MS2 spectra have dramatically increased the number of distinct peptides observed and the sequence coverage, although the increase in the number of proteins was less pronounced. More datasets will be added as they are deposited into the public ProteomeXchange repositories. Datasets that use new instrumentation, additional proteases beyond trypsin, and additional enrichment strategies are most likely to continue increasing the total number of proteins successfully detected in human plasma samples via MS. Challenges remain—when is the project considered closed? Human variability is enormous and so individual differences in the plasma proteome will be apparent and cloud the analyses and interpretation. For example, tissue leakage markers from growing juveniles need to be distinguished from similar or identical markers present in adults undergoing tissue healing and repair after pathology or injury. Moreover, nutritional status, diurnal variation and hormonal status will all need to be considered and hallmark proteins subclassified accordingly.

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Nonetheless, annotating the Human Plasma Proteome Project heralds an important achievement necessary to define and form baselines for disease biomarker discovery and monitoring before and during treatment.

Acknowledgements This work was funded in part by the National Institutes of Health grants R01GM087221 (EWD/RLM), R24GM127667 (EWD), U54EB020406 (EWD), P50GM076547 (RLM), U54ES017885 (GSO), and U24CA210967-01 (GSO). JMS acknowledges the Knut and Alice Wallenberg Foundation for funding to Human Protein Atlas, and the Erling-Persson Family foundation for support to the KTH Center for Applied Precision Medicine (KCAP).

The authors have no conflicts of interest to declare.

Supporting Information Supplementary Table 1: Listing of all experiments included in the Human Plasma PeptideAtlas 2017-04 along with selected attributes. Supplementary Table 2: GO analysis of contrasting the proteins detectable with the proteomic technologies. Supplementary Figure 1. Relative distributions of estimated human plasma protein concentrations from the 2017 Human Plasma PeptideAtlas build in relation to RNA abundance. Supplementary Figure 2. Relative distributions of estimated human plasma protein concentrations from the 2017 Human Plasma PeptideAtlas build in relation to annotated protein location.

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